UA61127C2 - Method for protecting human subjects from exposure to spin field with left-hand polarization and device for its realization - Google Patents

Abstract

The method for protecting human subjects from exposure to spin field with left-hand polarization, the device for realization of the method, and the method for installing the device relates to the medicine and the medical equipment intended for neutralizing the spin fields with left-hand polarization produced by the screens of the TV sets and displays. The set of the invention may be used in operating the household as well as industrial electronic equipment with displays and the power installations representing the sources of the torsion (spin) fields polarizing the space and the substances contained within the polarized space. The method is based on the generation of the additional compensating field with the opposite direction of spin polarization within the field produced by the displaying equipment. The device comprises the compensating component generating the static spin field directed oppositely to the spin component of the field generated by the display. Such a component represents at least two coaxial pipes mounted on the same base with the internal pipe possessing the least typical dimension of the transverse section d > 0.5Н, where Н is the height of the pipe. The shape of the transverse section of the coaxial pipes is chosen from the following set: the polygon withsides, the circle, the body of revolution of the arbitrary shape or the combination of the above-stated figures.

Description

Description of the invention

The group of inventions refers to the field of medicine and medical technology, designed to neutralize the influence of 2 spin fields with left polarization of space, which are created by screens of information display devices, mainly displays of video terminals, televisions, etc. devices.

The group of inventions can be widely used in the operation of both household and industrial radio, video electronic equipment and computer equipment, as well as in the operation of power devices, since any electromagnetic processes are accompanied by the appearance in the surrounding space of spin (torsion) 70 fields with the polarization of this space, as well as the substance located in this space. At the same time, in many cases, namely in cases with left polarization, such fields have a negative effect on the body of a person or an animal located in this space, and such an effect must be compensated.

The group of inventions can also be used to protect against the negative impact of geopathogenic zones and geobiological networks. 19 Spin fields with polarization of the surrounding space have a high penetrating ability and negligible attenuation in air, their influence on a living organism occurs at the atomic level.

In the case of a spin field with left polarization, there is a negative effect of the field on a living organism, which is manifested in the suppression of the energy of the cells of a living organism, since a spin field with left polarization induces a deficit of electron energy of the atoms of the cell's substance, namely carbon, hydrogen, oxygen, nitrogen atoms, calcium, sulfur, phosphorus and other elements that are part of living matter. This is due to the fact that in the case of a left-polarized field, the orbits of the electrons of the substance of the organism are shifted toward the energy minimum.

If the influence of the spin field with left polarization will be prolonged in time, and the energy deficit of electrons is statistically stable by its nature, the living organism first feels discomfort, and later - malaise, which turns into a disease of "unidentified etiology" with an unpredictable final result. with

In the case of a spin field with right polarization, on the contrary, there is a positive effect of the field on a living organism, Ge) which is manifested in an increase in the energy of the cells of a living organism, since a spin field with right polarization induces an excess of electron energy of the atoms of the cell substance. This is due to the fact that in the case of a right-polarized field, the electron orbits of the atoms of the body's substances are shifted towards the excess of energy. In order to stay in a stationary orbit, electrons eliminate their excess energy by transferring part of this energy to a living cell. with

Energy exchange in a living organism is always aimed at maintaining normal parameters of homeostasis, namely: body temperature, constancy of parameters of water-salt exchange, etc. It is mainly carried out due to the chemical energy of food, water and air oxygen. Normally, each person on average consumes 2 - Zkg of food, 2 - Zl of water and 1Zkg of air oxygen for this purpose. Thus, with a relatively constant and long-term impact on the human body of a spin field (radiation) with a left or left-handed ee, polarization of space, which causes a deficit of biological energy, a depressed state occurs in a person, which can turn into a disease (at first glance, of unknown etiology ) of any organ, system or tissue of the body, which, if no measures are taken, can have far-reaching consequences. "

A known method of protecting a person from the influence of a spin field (radiation) with left polarization of space, Z 50, which is created by the screen of an information display device, mainly a display of a video terminal, TV, etc. devices, by creating an additional field (radiation) with the opposite direction of the spin

From" polarization | see I. M. Seit-Umerov. A device for neutralizing harmful effects and a method of its manufacture.

Description to the patent of the Russian Federation Mo2146952 C, AbIM 1/16, 27.03.2000 according to the application of MOKA - 99120651/14 dated 5.10.99) (11.

The known method makes it possible to partially compensate for the harmful effect of the field with left polarization of space, created by the screen of the information display device, due to the use of form generators in the form of various geometric shapes made of material subjected to the torsion field in the process of forming the shapes.

However, the effectiveness of the known method is insufficient, since it cannot provide the intensity of the compensation field, which is equal to or even exceeds the intensity of the left-polarized spin field of the surrounding space, the harmful effect of which is compensated. This is due to the fact that the means used in the known method are limited by the possibility of using a finite, relatively small number of form generators, as well as by the insufficient efficiency of these means.

The method of protecting a person from the influence of a spin field (radiation) with left polarization of space, which is created by the 29 screen of an information display device, mainly a display of a video terminal, TV, etc.

HF) by creating an additional field (radiation) with the opposite direction of spin polarization (see Yuyu Pavlenko A.R., Bakhishev G.N., Orlov I.II. Device for protecting a person from the negative impact of video terminals. Description to the patent of Ukraine Mo18009, NOT) 29/06, 31.10.97 according to the application MoA-96103783 dated 02.10.96 (prototype) (21. because the known method provides a comparatively higher result, but its efficiency is also insufficient, since it also cannot provide the intensity of the compensating spin field, which is equal to or even exceeds the intensity of the compensating spin field with the left polarization of the surrounding space. This is a consequence of the same reason, namely, the efficiency of the known method of using a finite, comparatively small number of form generators, as well as the insufficient efficiency of these means. because Among the means , used to create a compensating spin field, a known device containing a dielectric base with generators formed on it frames of forms in the form of various geometric shapes, made of material exposed in the process of forming shapes based on the influence of a torsion (spin) field | see, for example, Melnikov V. E., Savushkin Yu. M., Tsvitinsky V. B., Shubin V. E. Milking device for protection against energy influences. Description to the patent of the Russian Federation Mo2140797 Si, AbITM 1/16, 10.11.99 non-application

KY-97114360/14 dated 07/20/13).

The known device forms a positively oriented microlepton field and thus allows to partially protect the space around it from the negative influence of pathogenic fields of a non-electromagnetic nature.

The effectiveness of the known device is insufficient because it is structurally limited by the relatively small 7/0 number of shape generators used.

The closest in terms of its technical essence and the result achieved to the claimed device is a device for protecting a person from the influence of a spin field (radiation) with left polarization of space, which is created by the screen of an information display device, mainly the display of a video terminal, TV, etc. device , containing a neutralizing element, which is a source of a shaped static spin field, the direction of action of which is opposite to the spin component of the field created by the information display device, and is made in the form of at least two coaxial nozzles placed on a common base. At the same time, the internal nozzle is made with the smallest characteristic size a of the cross-section, the value of which is a » 0.5Н, where Н is the height of the nozzle | see Pavlenko A.R., Pavlenko A.A. A device for protecting a person from the negative impact of video terminals and other electronic household appliances. Description to the patent of Ukraine Mo23759 А, НО1) 29/06, 16.06.98 2о according to the application Me OSHA-97030975 dated 03.05.97 prototype) (4).

The known device has a relatively high efficiency. However, this efficiency is still insufficient, as it is also structurally limited by the relatively small number of shape generators that can be used. In addition, the walls of the nozzles of the known device from the side of the common base are made unsharpened.

Therefore, the known device emits a left spin field from the side of the base common to the nozzles. This means that if the well-known device is incorrectly oriented in space relative to the screen of the information display device, its use may not have a positive, but a negative effect, since the intensity of its left field i) will increase the intensity of the left field of the screen.

The basis of the claimed group of inventions is the task of improving the method and device for protecting a person from the influence of a spin field (radiation) with a left polarization of space created by the screen Mzo of the information display device, based on the creation and use of a compensating element that is a source of a form static spin field (polarizer), the direction of action of which is opposite to the spin component of the field created by the screen of the information display device, which is not limited by the number of generators of "-forms" used.

The problem set in the invention is solved by the fact that in a known method of protecting a person from the influence of a spin (87 z5) field (radiation) with left polarization of space, which is created by the screen of an information display device, mainly the display of a video terminal, television, etc. devices, by creating of an additional field (radiation) with the opposite direction of spin polarization in the volume of the field created by the information display device, according to the invention, an additional compensating spin field with right polarization of the surrounding space is created with the help of a physical vacuum polarizer with right polarization "substance based on the effect of the previous of the right polarization of the polarizer substance. At the same time, the intensity of the compensating field is equal to or exceeds (but not less than) the intensity of the field with left polarization, which is created by the screen of the information display device, and the result of biological protection of the human body is determined by the difference in biological influence per person of both fields: spin field with left and spin field with right polarization of space.

The problem set in the invention is also solved by the fact that the polarizer of a physical vacuum has right polarization

Ge" substances are placed between the device (screen of the device) displaying information and the person.

The problem set in the invention can be solved by the fact that the physical vacuum polarizer with the right polarization of the substance is placed behind the information display device (device screen). - The problem set in the invention can also be solved by the fact that the physical vacuum polarizer with the right 5p polarization of the substance is placed coaxially with the information display device (device screen). The problem set in the invention is also solved by the fact that as a polarizer of a physical vacuum

And they use the atoms of the polarizer substance, which is polarized in advance with the possibility of creating a substance with right polarization.

In addition, the problem set in the invention is solved by the fact that in a known device (polarizer) for protecting two people from the influence of a spin field (radiation) with left polarization of the space created by the screen of the information display device, mainly the display of a video terminal, TV, etc. devices, which (F, contains a compensating element, which is a source of a shaped static spin field, the direction of action of which is opposite to the spin component of the field created by the information display device, and which is made in the form of at least two coaxial nozzles placed on a common base, while the internal nozzles are made with the smallest characteristic size 4 of the cross-section, the value of which is 4 » 0.5Н, where Н is the height of the nozzle, according to the invention, coaxial nozzles on a common basis are made with the shape of the cross-section selected from the series consisting of a polygon with the number sides t » 3, circles, bodies of rotation (of arbitrary shape), their combinations.

The problem set in the invention is also solved by the fact that the walls of the nozzles on the side of their free ends are made with 65 pointed edges.

At the same time, the angle of sharpening of the edge is o, x 1807.

Coaxial nozzles can be made with a wall that has the shape of a triangle in the longitudinal section with an angle at the top of Dr x 90.

Coaxial nozzles can be made with a shape that, in cross-section, is similar to the shape of the screen of the information display device.

Coaxial nozzles on a common basis can be placed with a constant step in the cross-section.

The value of the constant step It can be selected within the limits of i « i, where 4 is the smallest characteristic size (diameter) of the cross section of the pipe.

Coaxial nozzles on a common base can be placed with a variable pitch in the cross-section.

Coaxial nozzles on a common basis can be placed with a step of Her, which increases in the cross-section from the center to the periphery of the device.

Coaxial nozzles on a common basis can be placed with a step Y, which decreases in the cross-section from the center to the periphery of the device.

Coaxial spigots can be placed on a common base with a pitch of Я varying in the cross-section according to 75 with the law I - Ka), where a is the smallest characteristic size of the cross section of the inner spigot, and Ka) is a function chosen from the series consisting of whole or small rational function, power function, exponential function, logarithmic function, their combination.

The problem set in the invention can also be solved by the fact that the compensating element is made in a longitudinal cross-section that is plane-symmetrical with respect to the base. The compensating element can be made of 2 materials chosen from a series consisting of diamagnets, paramagnets, ferrimagnets, ferromagnets (polymers of natural and artificial origin, metals, metal alloys, alloys of metals with non-metals, non-metals), their combinations.

The problem set in the invention can be solved by the fact that the device is additionally equipped with at least one casing that covers the coaxial nozzles. Ha

The device (polarizer) can be made with a constant gap 5 between the casing and the ends of the coaxial nozzles. and)

The casing can be made in the form of biconvex (longitudinal cross-section plane) lens, and coaxial nozzles - with a height H that decreases from the center to the periphery of the device in plan.

The casing can be made in the form of a biconcave (longitudinal cross-sectional plane) lens, and the coaxial /-|ja« nozzles - with a height H that increases from the center to the periphery of the device in plan.

The casing can be made (in the plane of the longitudinal section) with a radius of curvature K » 0, where О is the smallest characteristic size of the device (polarizer) in plan. --

The casing (in the plane of the longitudinal section) can be made with a chord in the central part.

The length of the chord in the plane of the longitudinal section is the value B » a, where 4 is the smallest characteristic size of the cross section of the inner pipe. (Se)

The casing in the plane of the longitudinal section can be made in the form of two truncated cones connected by large bases, in which a rounded chamfer is made at the point of connection.

The problem set in the invention can also be solved by the fact that the device (polarizer) is additionally equipped with at least one two-dimensional (thin-film) element that creates a form-shaped static spin field of a three-dimensional structure with right polarization of space. - c The two-dimensional (thin-film) element can be placed on the side of the free ends of the coaxial nozzles. a Thin-film element can be made of a material selected from a series consisting of diamagnets, paramagnets, ferrimagnets, ferromagnets (polymers of natural and artificial origin, metals, metal alloys, alloys of metals with non-metals, non-metals), their combinations.

The device (polarizer) can be installed (placed) coaxially with the center of the screen of the display device (22) of information, from the side of its rear part and made with the possibility of three-dimensional overlapping by the compensating - spin field that is formed, the spin component of the field, which is created by the screen of the display device information - In addition, the problem set in the invention is solved by the fact that the device (polarizer) can be made with the possibility of adjusting the intensity and the sign of polarization of the compensating field that is formed, with the right polarization of the surrounding space by changing the parameter of the device, which is selected from the series, which consists of the shape of the cross section of the pipe, the value of the characteristic size 4 of the cross section of the pipe, the height of the pipe H, the angle o, the sharpness of the end edge of the coaxial pipes, the shape of the longitudinal section of the wall of the coaxial pipes, the value of the angle VD at the top of the triangular shape of the cross section of the coaxial nozzles, step sizes. Its placement of coaxial nozzles on the common

GF! basis, the nature of the distribution of its pitch from the center of the base to the periphery, the shape of the casing, the size of the gap 5 between the casing and the ends of the coaxial nozzles, the number of additional two-dimensional (thin-film) elements that create a form static spin field of a three-dimensional structure with right polarization of space, composition and structure the material of these additional elements, the nature of their placement in the device, their combination. 60 This implementation of the invention provides a significant increase in the efficiency of the method and device for protecting a person from the influence of a spin field (radiation) with left polarization of space, which is created by the screen of an information display device, preferably a display of a video terminal, TV, etc. devices.

The increase in efficiency is manifested in the fact that the intensity of the compensating spin field, which is obtained according to the claimed method, is equal to or exceeds the intensity of the field that is being compensated. This is a consequence of a significant increase in the efficiency of the used means. First of all, this is a consequence of the fact that the compensating element of the claimed device (polarizer), which is the source of the shape static spin field, thanks to the invention, has the opportunity to use an almost unlimited number of shape generators, which are the atoms of the substance of the compensating element itself, around which electrons rotate with an excess energy, that is, electrons, which are the source of the right-polarized spin field of the surrounding space. In addition, the obtained technical result is also a consequence of increasing the efficiency of other means.

Regardless of the shape, size, and composition of matter in various shape generators that perform the function of physical vacuum polarizers, all of them ensure the creation of spin fields of one or another polarization due to the electrons of atoms that are at the interface of media, namely a solid media, in which the atoms of the substance are one way or another ordered, and the vapor-gas-liquid medium, where the atoms of the substance are disordered.

In an unregulated environment, due to the chaotic movement of its particles, it is difficult to talk about the possibility of a spin field even when there is a simultaneous excess (or deficit) of energy in the electrons of the outer shells of atoms.

In an ordered (solid) medium, it is usually equally probable that there will be a deficit or surplus of energy in the electrons of the outer shells of the neighboring atoms. Therefore, the biological result of the negative influence of the spin field with left polarization is almost invisible under normal conditions.

It is possible to talk about the possibility of a spin field only when, in a local region of space at the boundary of the medium, the outer electrons of a group (many, perhaps even all) of the atoms of a solid substance simultaneously have either a deficit or an excess of energy. Then these atoms become sources of either a spin field with left polarization of the surrounding space (with a deficit of electron energy in their outer orbits), or sources of a spin field with right polarization of the surrounding space (with an excess of electron energy in their orbits).

For example, when a sheet of solid material is bent, the orbits of collectivized electrons at the boundary of the medium will be deformed. Among them, the trajectories of electron orbits on the outer shells will be deformed: from the inner side of the fold of the sheet, where the compression deformation takes place, the trajectories of the electron orbits will have i) a reduced radius and, therefore, these electrons will have a deficit of energy, and from the outer side, where stretching deformation takes place - the radius is increased and, therefore, these electrons (in higher orbits) will have an excess of energy compared to the stationary state. As a result, the atoms on the inner side of the bend will serve as the source of the spin field with the left polarization of the surrounding space, and the atoms on the outer side will serve as the source of the spin field with the right polarization of the surrounding space. with

Similarly, in the case of bombardment by a stream of charged particles of the inner surface of the screen of the device "- display of information, mainly the display of a video terminal, TV, etc. devices, on the inner side of the screen at the moment of collision (interaction) of an electron from the stream with the screen, a deformation of the structure - atoms occurs , bordering on an increase in the radius of electron orbits and, therefore, the appearance of an excess of atomic energy. This excess of energy is formed due to the energy of the electron from the stream and the redistribution of the energy of neighboring atoms, that is, ultimately - due to the energy of atoms on the outer surface of the screen, which at the same time experience a deficit of electron energy in the outer orbits and therefore move to orbits of a smaller radius. The result of this is the spin radiation of electrons with the left polarization of the space in front of the screen, which has a biopathogenic « 470 Influence on the operator and which must be compensated. in c The technical result achieved by the invention is that by using compensating

And an element in the form of a polarizer, the design of which is not limited by the number of shape generators used, and? in the capacity of which the atoms of the polarizer substance are used, bounding, the external orbits of electrons in which are deformed in the necessary way, that is, by using a more effective compensating element, in the volume of the field created by the screen of the information display device, create an additional compensatory

Ge" spin field (radiation) with right polarization of the surrounding space, the intensity of which is equal to or greater than (but not less than) the intensity of the field created by the screen of the information display device - and the result of the biological protection of the human body is determined by the difference between the simultaneous impact on a person of both - spin fields, i.e. fields with left and right polarization of space.

The design of the claimed device (physical vacuum polarizer), which is used for the purposes of the invention, also has a higher efficiency. | it also ensures obtaining a higher, compared to known

And constructions, technical results.

The invention is illustrated by the figures of the drawings, which schematically present variants of the claimed device (polarizer): Fig. 1, 9 - 15 - front view, longitudinal section; in fig. 2 - 8 - in Top view, cross section; Fig. 16 - 57 - illustrations of the results of checking the effectiveness of the invention.

A device (polarizer) for protecting a person from the influence of a spin field (radiation) with left polarization

F) the space created by the screen of the information display device, mainly the display of a video terminal, TV, etc. devices (fig. 1 - 14), contains a compensating element 1, which is a source of a form static spin field, the direction of which is opposite to the spin component the field created by the information display device. The compensating element is made in the form of at least two coaxial nozzles placed on a common base 2. At the same time, the inner nozzle Z is made with the smallest characteristic size a of the cross section, the value of which is 4 » 0.5Н, where Н is the height of the nozzle.

Coaxial nozzles 1, C on a common base 2 are made (fig. 2 - 8) with a cross-sectional shape selected from a series consisting of a polygon with the number of sides t » 3, a circle, a body of rotation (of arbitrary b5 shape), their combination .

Coaxial nozzles 1, C from the side of their free ends (Fig. 9) are made with pointed edges. The angle of the sharpening of the edge is 1807. Experimentally it has been confirmed that this design of the coaxial nozzles ensures an increase in the efficiency of the compensating element, because atoms of the material of the compensating element are located along the sharpened edge of the ends, in which electrons rotate in orbits of a larger radius.

In the embodiment shown in Fig. 10, the coaxial nozzles 1, Z in the longitudinal section have the shape of a triangle with an angle at the top of Д x 90". It has been confirmed experimentally that this design of the coaxial nozzles provides an even greater deformation of the external electron orbits of the atoms bordering , the material of the nozzles.

Coaxial nozzles 1, C are made with a shape that in cross-section is similar to the shape of the screen of the information display device. This implementation ensures the creation of a compensating spin field, similar in shape to the spin field being compensated.

Coaxial nozzles 1, C on a common base 2 are placed (Fig. 1) with a constant step 1 in the cross section.

It has been practically proven that this implementation ensures a comparatively more uniform distribution of the intensity of the compensating spin field over the volume 75.

The value of the constant step Kfig. 1) is chosen within the limits of и « a, where и is the smallest characteristic size (diameter) of the cross section of the pipe. This implementation provides a comparatively more uniform, optimal distribution of the intensity of the compensating spin field.

Coaxial nozzles 71, З on a common base 2 (Fig. 11) are placed with a variable cross-sectional step Her, which decreases (in cross-section) from the center to the periphery of the device. This makes it possible to increase the intensity of the compensation field from the center to the periphery.

In the variant of execution, in which the coaxial nozzles 1, З on a common base 2 are placed with a step of Я, which increases (in the cross-section) from the center to the periphery of the device (polarizer). This provides an increase in the intensity of the compensation field in the center of the volume. Ge

Coaxial nozzles 1, З are placed on a common base 2 with a pitch of Я, which varies in the cross section according to the law Я - Ка), where и is the smallest characteristic size of the cross section of the internal nozzle, and Ка) is a function that is selected from the series that consists of a whole or small rational function, a power function, an exponential function, a logarithmic function, their combination. This version provides a functional distribution of intensity in the volume of the compensating field. uh-

The compensating element (Fig. 1, 12) is made in a longitudinal cross-section plane-symmetrical relative to the base.

Experimentally, it was established that this version of the implementation provides an increase in the intensity cm of the compensating field by approximately 2 times. "-

The device (polarizer) is additionally equipped (fig. 1, 13, 14) with at least one casing 4, which covers the coaxial nozzles 1, 3. This version of the implementation ensures increased efficiency due to increased reliability of operation. (Se)

The device (polarizer) is made (fig. 1, 13, 14) with a constant gap 5 between the casing 4 and the ends of the coaxial nozzles 1, 3. This version of the implementation increases efficiency by improving the directional diagram of the compensating field, similar to the directional diagram of the field that is compensated . "

The casing 4 (Fig. 13) is made in the form of a biconvex (in the plane of the longitudinal section) lens, and the coaxial nozzles 1, З with a height H that decreases from the center to the periphery of the device. This version of the implementation - and this - has been confirmed practically - optimizes the directional diagram of the compensating spin field, matching it with the directional diagram of the field that is being compensated, which is created by the screen of the information display device. "» Casing 4 (Fig. 14) is made in the form of a biconcave (plane of the longitudinal section) of the lens, and the coaxial nozzles 1, З with a height H that increases from the center to the periphery of the device. This version of the design creates

Compensating spin field focused in the center of the volume.

Ge) Cover 4 (fig. 13, 14) is made (in the plane of the longitudinal section) with a radius of curvature K z» 0, where O is the smallest - the characteristic size of the compensating element. This version provides the optimal shape of the directional diagram. - Casing 4 (Fig. 1) is made (in the plane of the longitudinal section) with chord 5 in the central part. At the same time, t 50 the length of the chord in the plane of the longitudinal section is the value B » a, where 4 is the smallest characteristic size of the cross section of the internal pipe 3. This variant of execution provides not only the optimal shape of the directional diagram, but also optimal ergonomic properties.

The casing 4 in the plane of the longitudinal section (Fig. 15) is made in the form of two truncated cones b connected by large bases, in which a rounded chamfer 7 is made at the point of connection. This variant of execution also 22 optimizes the directional diagram and ergonomic properties of the claimed device .

Gee! The device (polarizer) is additionally equipped (fig. 1, 13 - 15u) with at least one two-dimensional (thin-film) element 8, which creates a Fermi static spin field of a three-dimensional structure with right polarization of space. In this variant, the efficiency of the device is significantly increased due to an increase in the number of elementary polarizers in the form of electrons in the excited orbits of the atoms of the film substance. 60 The two-dimensional (thin film) element 8 (fig. 1, 13 - 15) is placed on the side of the free ends of the coaxial nozzles 1, C under the housing cover. This provides one of the options for the device.

The thin-film element 8 is made of a material selected from a series consisting of diamagnets, paramagnets, ferrimagnets, ferromagnets (polymers of natural and artificial origin, metals, alloys of metals with nonmetals, nonmetals), their combinations. This provides another version of the device. 65 The device (polarizer) is installed (placed) (fig. 1 - 153 coaxially with the center of the screen of the information display device is not shown), from the rear part of it and is made with the possibility of volumetric overlap with the compensating spin field, which forms the field of the generated spin component information display device screen. This provides the best possible version of the device.

The device (polarizer) is made (fig. 1 - 153 with the possibility of adjusting the intensity and the sign of polarization

The compensatory field that forms, with the right polarization of the surrounding space due to the change of the device parameter, which is chosen from a series consisting of the shape of the cross section of the nozzle, the value of the characteristic size 4 of the cross section of the nozzle, the value of the height H of the nozzle, the value of the angle o, the sharpness of the end edge coaxial nozzles, the shape of the longitudinal section of the walls of the coaxial nozzles, the angle D at the top of the triangular shape of the cross section of the coaxial nozzles, the size of the 70 pitch, the placement of the coaxial nozzles on a common base, the nature of the distribution of the pitch from the center of the base to the periphery, the shape of the casing, the size of the gap 5 between casing and ends of coaxial nozzles, the number of additional thin-film (two-dimensional) elements that create a shaped static spin field of a three-dimensional structure with right polarization of space, the composition and structure of the material of these additional elements, the nature of their placement in the device, their combination.

The claimed method is carried out as follows.

A polarizer with right polarization of matter is installed in the volume of the field created by the screen of the information display device. In this case, the polarizer is placed between the screen of the information display device and the operator or behind the screen of this device. During the operation of the information display device, the outer surface of the screen of this device creates a field with left polarization of space, which interacts with the electronic shells of the atoms of the polarizer with right polarization. Since these electron shells of the atoms of the polarizer substance, located at the boundary of the media, are shifted towards the excess (compared to the stationary state of the electron orbits) of the energy of the electrons located on them, they create a spin field with a right polarization of the surrounding space. Thus, in the same volume, an additional compensating spin field with right polarization of the surrounding space is created, the intensity of which is equal to or Ge! exceeds (but not less than) the intensity of the field created by the screen of the information display device. at

One of the features of spin fields is their lack of energy and energy characteristics. | this is one of the reasons for the weak absorption of spin fields by the environment. Another feature of spin fields is that they do not obey the principle of superposition, i.e. vectors of spin fields with opposite polarization do not add up either geometrically or arithmetically. At the same time, the spin field has such a characteristic as the field intensity, which depends on the number of simultaneously acting elementary polarizers: the more elementary polarizers with unidirectional polarization of space operate simultaneously in a certain volume, the greater will be the intensity of the spin field, which created in this volume. This gives an opportunity due to a significant increase in the number of elementary polarizers to ensure the creation of a spin field with right polarization, the intensity of which is equal to or greater than (but not less than) the intensity of the spin field, which is compensated, with left polarization. Both fields simultaneously coexist in (Se) one and the same volume of space, both fields simultaneously affect the human body, which is located in the volume of action of the fields. However, the direction of their action on the human body is opposite. | since the intensity of the spin field with right polarization is not less than the intensity of the field with left polarization, the result of biological protection of the human body, which is determined by the difference in the biological effect on a person of both fields: the field with left polarization and the field with right polarization of space, will at least not be negative. According to the invention, the intensity of the spin field with right polarization is usually provided by constructive means clearly greater than the intensity of the spin field with left polarization. Therefore, the total protective biological effect "" of joint action on a person of both fields is clearly positive.

The claimed device (physical vacuum polarizer), which is shown in Fig. 1 - 15, works as follows.

The device (polarizer) is placed near or directly on the screen of the information display device. (o) The best option for using the invention is when the device (polarizer) is placed coaxially with the screen - the information display device, or between the screen of the device and the operator, or behind the screen of this device.

The compensating element of the device, which is a collection of a very large number of elementary polarizers in the form of excited orbits of electrons of the atoms of the polarizer substance and is made in accordance with the invention, is capable of creating a spin field with right polarization of space. At the same time, the intensity of such a field with the right polarization of space, thanks to constructive means, is always greater than or equal to (but not lower than) the intensity of the spin field, which is compensated, with the left polarization of space.

This ensures complete neutralization of the biopathogenic influence of the left-polarized field.

The effectiveness of the claimed method and the effectiveness of the claimed device are confirmed by the following studies, which are specific examples of the implementation of the invention.

Example 1. o In the volume of the spin field with left polarization of the surrounding space, which is formed by the screen of a personal computer with a size of 15" diagonally, an additional compensating spin field with right polarization was created based on the effect of the previous polarization of the polarizer substance. At the same time, the intensity because the compensating spin field exceeded the intensity of the field with left polarization, which was created by the computer screen.

The intensity of the compensating spin field with right polarization was provided using a device to protect a person from the influence of a spin field with left polarization, which contains a compensating element that is a source of a form static field with right polarization, and is made in the form of 8 coaxial 65 cylindrical nozzles 1, From, placed on a common basis 2. At the same time, the device was placed between the computer screen and the operator. The inner pipe Z of the device was made with the smallest characteristic size -

the internal diameter of the cross section, which was 4 - 4 mm and the value of which is smaller than half the height of the nozzle H - 1 Ω. The walls of the nozzles from the side of their free ends were made in a longitudinal section in the shape of a triangle with pointed edges at the top. The angle of sharpening of the edges was ro - 12". / The coaxial nozzles were placed on the common base of the neutralizing element with a constant step in the cross section

Ii - 2mm « and - 4mm. The compensating element of the protection device (neutralizer) was made in a longitudinal section plane-symmetrical relative to the base. The device was made of a paramagnet - polypropylene and equipped on both sides with a casing 4, made in the form of a biconvex lens in the plane of the longitudinal section, and the coaxial nozzles were made with a height of H - 10 mm, which decreased from the center to the periphery of the device. Radius 7/0 The curvature of the casing in the plane of the longitudinal section was K - 100mm » О - b2mm, where О is the smallest characteristic size (diameter) of the device (polarizer) in plan. The casing was made in the plane of the longitudinal section with bilateral chords in the central part. At the same time, the length of each chord in the plane of the longitudinal section was B - ZOmm » a - 4mm. The device (polarizer) was equipped with two thin-film elements 8, which create a shaped static spin field of a three-dimensional structure with right polarization. 7/5 Thin-film elements were placed on the side of the free ends of the coaxial nozzles 1, Z under the covers of the casing 4 in the gaps, the size of each of which was 5 - 0.5 mm. The thin-film element 8 was made of a diamagnet - a 0.05 mm thick fluorescein film. This implementation of the claimed device (polarizer) due to its enhanced properties and a significantly increased number of elementary sources of polarization in the claimed device ensured, due to the use of more effective constructive means, the creation of a compensating spin field with right polarization, the intensity of which was clearly higher than the intensity of the field with left polarization, which created by the screen of a personal computer and which is compensated.

The result of the biological protection of the human organism - the computer operator (protective effect) was checked by the difference of the simultaneous effect on the person of both fields: fields with left polarization and fields with right polarization. In all cases of inspection, a positive result was obtained. Ha

The verification procedure was as follows: the effectiveness of the claimed method was verified by studying the change in the state of biologically active points (BAT) using electroacupuncture diagnostics according to R. Foll. and)

A group of 112 people (112) who used the claimed invention were tested. The control group consisted of 88 men (88) who did not use the claimed invention.

The tests were carried out in the laboratory of the "Era Vodoliya" enterprise, Kyiv. h-

Changes in parameters were measured in each operator from the group under investigation and from the control group

BAT (a total of 32 BAT) and chakra point projection parameters (PTU) - a total of 28 PTU according to the standard method, namely after 5, 30 and 60 minutes after the patient starts working on the computer. The results of measurements at all 60 points were statistically processed and graphically displayed on aurograms 11, 12 and 13 in two projections: a front view (Fig. 16) and a side view (Fig. 17). -

The analysis of the received data and aurograms 11 - 13 in Fig. 16, 17 shows that compared to the initial state, which "(o is characterized by aura 11, which is the same for both groups of operators, the state of operators in the control group, which is characterized by aura 12, due to The working environment on the computer worsens, as the activity of BAT in the operators of the control group decreases by 15 - 3095. At the same time, in the operators of the group under investigation, who "used the claimed invention, the activity of electroacupuncture points not only did not decrease due to but it even increased by 5 - 10905. - с Example 2. ц We used the conditions of the previous example, but the declared device (polarizer) was placed behind "» the computer screen. Results similar to the results of example 1 were obtained.

Example 3.

We used the conditions as in the previous examples, but the declared device (polarizer) was placed

Ge) coaxial to the computer screen. Similar results were obtained. -3z Example 4.

We used the conditions as in the previous examples, but as the claimed device (polarizer) - we used atoms of a substance that had been polarized in advance by means of its surface treatment with the possibility of deformation of the electronic orbits of the atoms of the substance of the polarizer. Similar results were obtained, which were statistically processed and presented as examples of illustrations in the form of diagrams and histograms in Fig. 18 - 23: "And the chakras of the right side of the body of the operators - in Fig. 18 and 19; the chakras of the surface of the right palm - in Fig. 20 and 21; right ear chakras - in Fig. 22 and 23.

The following chakras are conventionally marked on the indicated figures along the abscissa axis with points 1 - 7: 1 - Muladhara chakra, 2 - Swadhisthana chakra, Z - Manipura chakra, 4 - Anahata chakra, 5 - Vishudha chakra, b - Ajna chakra, 7 - O Sahasrara chakra ; along the ordinate axis - the magnitude of the electric potential in conventional units (biological activity). Analysis of the obtained data gives the same result as in example 1.

Example 5. 60 We used the same conditions as in the last example, but a qualitative assessment of the state of BAT and PTC was carried out by the method of gas-discharge visualization of the Kirlian effect using a VEO COM camera, according to K. Korotkov | see V. G. Korotkov

Aura and Kirlian effect. - On Sat. "From the Kirlian effect to bioelectrography", series "Information. Consciousness.

Life", 1998, P. 24 - 112) (5). We obtained results, which after statistical processing are presented in Fig. 24 - 57: Fig. 24 shows a diagnostic table of aurograms of the fingers of the patient's left and right hands, which are projections of 65 Organs and systems of the body on the surface of the fingertips, which was obtained by computer registration during the stimulation of the torsional radiation of the human body by an electromagnetic field with the enhancement of the image in a gas discharge.

Based on the aurograms of 10 fingers, the computer builds a general aurogram of the patient's body, which allows you to observe the state and changes of the person's fields on the computer monitor screen and conduct automated diagnostics; Figures 25 - 34 and 35 show statistically processed aurograms of a patient of the research group, obtained from the projections of the fingers of both his hands and the whole body, which reflect his initial state and do not statistically differ from the aurograms of the initial state of the same patient of the control group; Fig. 36 - 45 and 46 show the aurograms of the same patient of the study group obtained through ZOkhv. after starting his work on the computer without using the claimed invention; Fig. 47 - 56 and 57 show the aurograms of the same patient of the study group, obtained through ZOkhv. after 7/0 the start of his work on the computer using the claimed invention.

The analysis of the obtained data showed that in patients of the control group, that is, in operators who do not use the claimed invention, the activity of acupuncture points and projections of chakra points decreases by 15 - 3095 after 3 minutes after starting work on the computer compared to the initial state. And for the operators using the declared protection device (polarizer), that is, for the operators of the researched group, the /5 decrease in the activity of the indicated points does not occur. Moreover, they have an increase in the activity of the indicated points on Z - 5905.

Example 6.

The same conditions as in example 5 were used, qualitative assessment was carried out by the Kirlian method and the same results were obtained. The analysis of the obtained results shows that when the operator works on the computer without using the 2o claimed protection device (polarizer), the field structures in the head 23, throat 24, and chest 25 regions are destroyed. This is clearly visible when comparing the aurograms in figures 35 and 46. In that at the same time, these effects are not observed when using the declared protection device (polarizer) - see aurograms in Fig. 35 and 57 or aurograms in Fig. 46 and 57.

This indicates that the effect of the protection device (polarizer) that creates a spin field with right polarization on the operator ensures complete neutralization of the negative (biopathogenic) influence of a spin field with left polarization, which is created by a personal computer. and)

Thus, the experimental verification confirms that the technical problem set in the invention has been solved, namely: an improved method and device for protecting a person from the influence of a spin field (radiation) with left polarization of space, which is created by the screen of an information display device, based on the creation and M zo The use of a compensating element, which is a source of a form static spin field (polarizer), the direction of which is opposite to the spin component of the field created by the screen of the information display device, due to the use of an unlimited number of form generators. "-

At the same time, each object of the claimed group of inventions and the whole group in general, in our opinion, meet the criteria of the invention, namely: the "novelty" criterion, the "inventive level" criterion, and the "industrial applicability" criterion. "at

Sources of information taken into account: 1. 1. M. Seit-Umerov. A device for neutralizing harmful effects and a method of its manufacture. - Description to the patent of the Russian Federation Mo2146952 S. AbI1TM 1/16, 27.03.2000 Or. according to the MOKO application - 99120651/14 dated 10.5.99. (11. 2. Pavlenko A.R., Bakhyshev G.P., Orlov I.Y. Device to protect a person from the negative influence of video terminals. - Description to the patent of Ukraine Mo18009 A, NOT) 29/06, 31.10.97. according to the application MoOA-96103783 dated 02.10.96. - prototype (21.

Z. Melnikov V.E., Savushkin Yu.M., Tsvitsynskyi V.B., Shubin V.E. Device for protection against energy influences - Description to the patent of the Russian Federation Mo2140797 S. AbITM 1/16, 27.03.200Or. according to the application KO-99120651/14 dated 10.5.99. |ZI. 4. Pavlenko A.R., Pavlenko A.A. A device to protect a person from the negative impact of video terminals and other electronic household appliances. - Description to the patent MoSHA-23759 A, NOTE) 06/29, 06/16/98. upon application

F MoOA-97030975 dated 03/05/97. - prototype |4|. 5. Korotkov H. K. Aura and the Kirlian effect. - On Sat. "From the Kirlian effect - to bioelectrography", series - "Information. Cognition. Life", St. Petersburg, 1998, pp. 24 - 112 |bI. - she is 70

Claims (32)

The formula of the invention is that 1. A method of protecting a person from the influence of a spin field with a left polarization of space, which is created by the screen of an information display device, mainly a display of a video terminal, TV and similar devices, by creating an additional field with the opposite direction of spin polarization in the volume of the field, which is created by the information display device , which differs in that they create an additional compensatory (Ф) spin field with right polarization of the surrounding space using a physical vacuum polarizer with GI right polarization of matter based on the effect of previous polarization of the polarizer matter, while the intensity of the compensatory field is equal to or exceeds the intensity of the field with left polarization , which is created by the screen of the information display device, and the result of the biological protection of the human body is determined by the difference in the effect on the person of the spin field with the left and the spin field with the right polarization of space. 2. The method according to claim 1, which differs in that the physical vacuum polarizer with the right polarization of the substance is placed between the screen of the information display device and the person. 65 Z. The method according to claim 1, which differs in that the physical vacuum polarizer with the right polarization of the substance is placed behind the screen of the information display device. 4. The method according to any of claims 1-3, which is characterized by the fact that the physical vacuum polarizer with the right polarization of the substance is placed coaxially with the screen of the information display device. 5. The method according to claim 1, which differs in that as a polarizer of a physical vacuum, atoms of the polarizer substance are used, which are polarized in advance with the possibility of creating a substance with right polarization. 6. The method according to claim 5, which differs in that the preliminary polarization of the polarizer substance is carried out by its surface treatment with the possibility of deformation of the electronic orbits of the atoms of the polarizer substance. 7. A device for protecting a person from the influence of a spin field with a left polarization of space created by a 7/0 screen of an information display device, mainly a display of a video terminal, TV and similar devices, which contains a compensating element that is a source of a shaped static spin field, the direction of which opposite to the spin component of the field, which is created by the information display device, and which is made in the form of at least two coaxial nozzles placed on a common base, while the inner nozzle is made with the smallest characteristic size a of the cross section, the value of which is a»o5n, where Н is the height of the nozzle , which differs in that the coaxial nozzles on the common base of the compensating element are made with a cross-sectional shape that is selected from a series consisting of a polygon with the number of sides tm", a circle, a body of rotation of an arbitrary shape, their combination. 8. The device according to claim 7, which differs in that the walls of the nozzles on the side of their free ends are made with pointed edges. 9. The device according to claim 7, which is characterized by the fact that the angle of sharpening of the edge does not exceed 180". 10. The device according to claim 7, which is characterized by the fact that the coaxial nozzles are made with a wall that has the shape of a triangle in the longitudinal section with an angle 2 at the top that does not exceed 90". Ha 11. The device according to claim 7, which is characterized by the fact that the coaxial nozzles have a shape that, in cross-section, is similar to the shape of the screen of the information display device. 12. The device according to claim 7, which is characterized by the fact that the coaxial nozzles are placed on a common base with a constant cross-sectional step of 1. 13. The device according to claim 12, which differs in that the value of its constant step is selected within - зо и5а, сх where a is the smallest characteristic size or diameter of the cross section of the nozzle. 14. The device according to claim 7, which differs in that the coaxial nozzles are placed on a common base with the same variable pitch in the cross section. "- 15. The device according to claim 14, which is characterized by the fact that the coaxial nozzles on a common base are placed with a step y, which increases in cross-section from the center to the periphery of the device. (Se) 16. The device according to claim 15, which is characterized by the fact that the coaxial nozzles on a common base are placed with a step Her, which decreases in the cross-section from the center to the periphery of the device. 17. The device according to claim 15 or 16, which differs in that the coaxial nozzles are placed on a common base "with a step of ЯЙ, which changes in the cross section according to the law -КФ), ts where a is the smallest characteristic size of the cross section of the internal nozzle, and (a) - a function that is chosen from a series consisting of a whole or fractional rational function, a power function, an exponential function, a logarithmic function, or their combination. 18. The device according to claim 7, which is characterized by the fact that the compensating element is made in a longitudinal section plane-symmetrical with respect to the base. (2) 19. The device according to claim 18, which is characterized by the fact that the compensating element is made of a material selected from the group consisting of diamagnets, paramagnets, ferrimagnets, ferromagnets, their combination. 20. The device according to claim 7, which is characterized by the fact that it is additionally provided with at least one casing, which covers the coaxial nozzles. from 20 21. The device according to claim 20, which differs in that it is made with a constant gap 5 between the casing and the ends of the coaxial nozzles. "M 22. The device according to claim 21, which is characterized by the fact that the casing is made in the form of a biconvex lens in the plane of the longitudinal section, and the coaxial nozzles have a height H that decreases in the plan from the center to the periphery of the device. 23. The device according to claim 20, which is characterized by the fact that the casing is made in the form of a lens biconcave in the plane of the longitudinal section 22, and the coaxial nozzles have a height H that increases in plan from the center to the periphery of the device. GF) 24. The device according to claim 22 or 23, which is characterized by the fact that the casing is made in the plane of the longitudinal section with a radius of curvature about вх, where О is the smallest characteristic size of the device in plan. 6o 25. The device according to claim 24, which differs in that the casing in the plane of the longitudinal section is made with a chord in the central part. 26. The device according to claim 25, which differs in that the length of the chord in the plane of the longitudinal section is the value я, because where 4 is the smallest characteristic size of the cross section of the inner pipe. 27. The device according to claim 20, which differs in that the casing in the plane of the longitudinal section is made in the form of two truncated cones connected by large bases, in which a rounded chamfer is made at the point of connection. 28. The device according to claim 7, which is characterized by the fact that it is additionally equipped with at least one two-dimensional thin-film element, which creates a shaped static spin field of a three-dimensional structure with right polarization of space. 29. The device according to claim 28, which is characterized by the fact that the two-dimensional thin film element is placed on the side of the free ends of the coaxial nozzles. 30. The device according to claim 29, which is characterized by the fact that the thin-film element is made of a material selected from the group consisting of diamagnets, paramagnets, ferrimagnets, ferromagnets, and combinations thereof. 31. The method of using the device given in claims 7-30, which is made with the possibility of compensating the spin field with left polarization of the space, which is created by the screen of the information display device, mainly the display of a video terminal, TV and similar devices, by creating an additional field with the opposite /5 direction of the spin polarization in the volume of the field created by the information display device, which differs in that the device is installed coaxially to the center of the screen of the display device from the rear side of it, and the device itself is made with the possibility of volumetric overlap with the compensating spin field, which is formed by the spin component fields created by the screen of the information display device. 32. The method according to claim 31, which is distinguished by the fact that it is made with the possibility of adjusting the intensity and the sign of polarization of the compensation field with the right polarization of the surrounding space, which is formed by changing the parameter of the device, which is selected from the series consisting of the shape of the cross section of the nozzle, values of the characteristic size a of the cross-section of the pipe, the height of the pipe H, the angle of the sharpening of the end edge of the coaxial pipes, the shape of the longitudinal section of the wall of the coaxial pipes, the value of the angle 82 at the top of the triangular shape of the cross-section of the coaxial pipes, the values of Step Y of placing the coaxial pipes on a common base , the nature of the distribution of the size of the pitch from the center of the base to the periphery, the shape of the casing, the size and uniformity of the distribution of the gap 5 between the casing and the ends of the coaxial nozzles, the number of additional thin-film two-dimensional elements that create a form static spin field of a three-dimensional structure with right the polarization of space, the composition and structure of the material of these additional elements, the nature of their placement in the device and their combination. - s «- «- (Se) - and? (o) - - ime) that ime) 60 b5